Abstract
We theoretically demonstrate that interacting symmetry-protected topological (SPT) phases can be realized with ultracold spinful bosonic atoms loaded on the lattices which have a flat band at the bottom of the band structure. Ground states of such systems are not conventional Mott insulators in the sense that the ground states possess not only spin fluctuations but also non-negligible charge fluctuations. The SPT phases in such systems are determined by both spin and charge fluctuations at zero temperature. We find that the many-body ground states of such systems can be exactly obtained in some special cases, and these exact ground states turn out to serve as representative states of the SPT phases. As a concrete example, we demonstrate that spin-1 bosons on a sawtooth chain can be in an SPT phase protected by $\mathbb{Z}_2 \times \mathbb{Z}_2$ spin rotation symmetry or time-reversal symmetry, and this SPT phase is a result of spin fluctuations. We also show that spin-3 bosons on a kagome lattice can be in an SPT phase protected by $D_2$ point group symmetry, but this SPT phase is, however, a result of charge fluctuations.
Highlights
Symmetry-protected topological (SPT) phases refer to the quantum phases of those short-range entangled ground states that can never be smoothly deformed into product states while preserving certain symmetry
We theoretically demonstrate that interacting symmetry-protected topological (SPT) phases can be realized with ultracold spinful bosonic atoms loaded on the lattices which have a flat band at the bottom of the band structure
We demonstrate that spin-1 bosons on a sawtooth chain can be in an SPT phase protected by Z2 × Z2 spin rotation symmetry or time-reversal symmetry, and this SPT phase is a result of spin fluctuations
Summary
Symmetry-protected topological (SPT) phases refer to the quantum phases of those short-range entangled ground states that can never be smoothly deformed into product states while preserving certain symmetry. (Intuitively, since the s-wave collision is spin-dependent by its nature, when the bosons are in a certain spin state, the collision between them can be avoided even if the bosons are very close to each other.) When certain parameters in the Hamiltonian are fine-tuned, the above configuration (lattice fully packed with CLSs) becomes the exact and unique ground state, and the state turns out to serve as a representative state of the symmetry-protected phases of the system. With fine-tuned interactions, |GS f ,X can be exactly mapped to |VBS f ,X , provided that the lattice structures of X and X satisfy a certain relation This proves that |GS f ,X is the exact and unique ground state of the itinerant spin- f model.
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